Electric-field imager for assays

ABSTRACT

This disclosure describes an electric-field imaging system and method of use. In accordance with implementations of the electric-field imaging system, a fluid sample can be placed on top of a pixel-based impedance sensor. An image of the target analytes can be created immediately afterwards. From this image, computer imaging algorithms can determine attributes (e.g., size, type, morphology, volume, distribution, number, concentration, or motility, etc.) of the target analytes. The electric-field imaging sensor can be used for a variety of agglutination or agglomeration assays.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation-in-part of U.S. Non-Provisional patent application Ser. No. 14/859,943, filed Sep. 21, 2015, and titled “ELECTRIC-FIELD IMAGER FOR ASSAYS,” which claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 62/156,954, filed May 5, 2015, and titled “ELECTRIC-FIELD IMAGER FOR VISUALIZING CELLS.” U.S. Non-Provisional patent application Ser. No. 14/859,943 and U.S. Provisional Patent Application No. 62/156,954 are incorporated herein by reference in their entireties.

BACKGROUND

Flow cytometry is the dominant method of counting red blood cells, white blood cells, and so forth. When a company is developing a flow cytometer, validation of the results from the machine is done by a human looking through a microscope and visually counting the cells on a sample smeared over a glass slide. Electric Cell-substrate Impedance Sensing (ECIS) determines how fast cells grow in a laboratory dish by measuring the impedance of the cells as they are growing. The cells block the electric field lines, and impedance increases as the cells grow and cover more and more of the sensor. Once the cells have completely covered the sensor, the impedance asymptotes.

The existing methods suffer from several limitations. For example, flow cytometer results take some time to obtain because blood samples are usually taken to a laboratory to be prepared and then run through the flow cytometer. Visual inspection to count cells is tedious for the human who has to do it and is of course prone to human error. Visual inspection results also take a considerable amount of time to obtain for the same reasons as the flow cytometer results. ECIS provides a single scalar measurement for the growth rate of a colony of cells on top of the sensor. No information is available as to how the cells cover the sensor, how many cells there are, concentration of cells, how the cells move as they grow, or the like.

SUMMARY

This disclosure describes an electric-field imaging system and method of use. In accordance with implementations of the electric-field imaging system, a fluid sample (e.g., a blood sample or other biological sample) can be placed on top of an impedance based sensor. An image of the cells can be created immediately afterwards. From this image, computer imaging algorithms can determine attributes, such as size, type, morphology, volume, distribution, number, concentration, or motility of target analytes (e.g., microparticles, viruses, cells, or labeled beads).

In some embodiments, an electric-field imaging system relies on a substantially vertical electric field. For example, if an electrode is above the electric field sensor array, then a vertical electric field can be formed between the top electrode and the sensor array. In some implementations, the metal layer of an integrated circuit can form the electric field sensor array. The sensor can have a pitch suitable for imaging red blood cells, white blood cells, platelets, or the like.

In some embodiments, an electric-field imaging system relies on a substantially horizontal electric field. For example, a single pixel, a line of pixels, or a regions of pixels can be driven, and the rest of the pixels in the electric field image sensor can receive the electric field. The presence of particles like microparticles, viruses, cells, in the fluid disturbs the electric field, resulting in a change of impedance from driving pixel to receiving pixel. Each pixel can be formed by a plate of metal.

This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

DRAWINGS

The Detailed Description is described with reference to the accompanying figures. The use of the same reference numbers in different instances in the description and the figures may indicate similar or identical items.

FIG. 1 is a schematic view of an electric-field imager implemented in accordance with an embodiment of this disclosure.

FIG. 2A illustrates an example of agglutination assaying with an electric-field imager, wherein beads covered by antibodies are dispersed.

FIG. 2B illustrates an example of agglutination assaying with an electric-field imager, wherein beads covered by antibodies are agglutinated.

FIG. 3 is a schematic side view of an electric-field imager implemented in accordance with an embodiment of this disclosure, wherein the electric-field imager is configured to detect disturbances in a vertical electric field.

FIG. 4 is a schematic side view of an electric-field imager implemented in accordance with an embodiment of this disclosure, wherein the electric-field imager is configured to detect disturbances in a horizontal electric field.

FIG. 5 is flow diagram illustrating a method of imaging microparticles, viruses, cells or beads in a fluid sample with an impedance based sensor, such as the electric field imager illustrated in FIGS. 1 through 4 in accordance with various embodiments of this disclosure.

DETAILED DESCRIPTION Overview

A pixel-based image sensor is disclosed in which each pixel senses changes in the electric field above it to determine the presence of microparticles, viruses, cells, beads and also one or more attributes, such as size, type, morphology, distribution, concentration, number of microparticles, viruses, cells, beads, and so forth. In embodiments, the pitch of the pixels can vary from 10 nm to 20 um. Each pixel can be configured to measure impedance. In some embodiments, the sensor is implemented on an integrated circuit. The sensor can also be formed from patterned or printed conductors on a substrate such as glass or plastic, where at least one integrated circuit electrically connected to the conductors can be configured to measure the impedance.

Example Implementations

FIGS. 1 through 4 illustrate an electric-field imaging system 100 in accordance with various embodiments of this disclosure. Those skilled in the art will appreciate that the embodiments illustrated in the drawings and/or described herein may be fully or partially combined to result in additional embodiments. Substitutions and other modifications can also be made without departing from the scope of this disclosure. Accordingly, the illustrated and described embodiments should be understood as explanatory and not as limitations of the present disclosure.

In an embodiment illustrated in FIG. 1, an electric-field imaging system 100 is shown to include a plurality of conductive metal panels 102 making up the pixels of an active sensor area. In some implementations, the metal layer of an integrated circuit can form the electric field sensor array. The active sensor area can receive a fluid sample including target analytes (e.g., viruses, prions, sperm, cells, beads, biological microparticles, etc.), which can be deposited over the active sensor area for electric-field imaging based on changes in impedance or charge detected at respective ones of the metal panels 102. For example, FIG. 1 shows a cell 110 on the active sensor area, where the sensor pitch (e.g., panel length, width, and/or panel-to-panel separation) may be appropriate for imaging the cell 110 and various cellular structures (e.g., the cell's nucleus 112). A sensor pitch in the range of 1 um is shown in FIG. 1; however, it is noted that the sensor pitch can be larger or smaller to suit different applications. In some embodiments, the pitch is anywhere from approximately 10 nm to 20 um. To properly image individual target analytes (e.g., individual cells or microparticles of interest), the sensor pitch may be higher frequency than a Nyquist spatial sampling rate suitable for detecting a smallest member of a group of target analytes. In some implementations, detection of cellular structures or morphology can be used to distinguish between different types of biological cells (e.g., white blood cells vs. red blood cells).

The system 100 can include transmitter circuitry configured to generate drive signals that are applied to one or more of the metal panels 102 or applied to a driving electrode positioned relative to the panels 102 (e.g., as shown in FIG. 3). In some embodiments, the transmitter can include a frequency generator that feeds into one or more digital to analog converters (DACs) to generate one or more drive signals. The system 100 can also include receiver circuitry coupled to the metal panels 102, and configured to sense changes in impedance or charge detected by the metal panels 102. In some embodiments, the receiver can include one or more analog to digital converters (ADCs) configured to receive an impedance, voltage, or current reading from each of the metal panels 102 to sense changes in impedance or charge, which can result from the presence of target analytes in proximity of one or more of the metal panels 102. In some embodiments, the receiver circuitry can also include a frontend filter (e.g., low pass filter) configured to remove noise or signal components attributable to the fluid containing the target analytes, drive signal artifacts, and so forth.

The system 100 may further include processing logic embodied by a programmable logic device, a controller/microcontroller, a single or multiple core processor, an ASIC, or the like. For example, the system 100 can include a processor 104 coupled to a memory 106 (e.g., solid-state disk, hard disk drive, flash memory, etc.), where the memory includes program instructions 108, such as one or more software modules executable by the processor 104. In some embodiments, the processing logic can control transmission and receipt of signals to and from the metal panels 102. For example, the processing logic may be coupled with receiver and/or transmitter circuitry. The processing logic may be configured to generate an image based on electrical signals associated with changes in impedance or charge detected at one or more of the metal panels 102. In some embodiments, the processing logic can include fast Fourier transform (FFT) and impedance sense algorithms. The processing logic can further include one or more computer imaging software modules executable by a processor/controller to identify attributes of target analytes in the generated electric-field image. For example, the computer imaging modules may cause the processor/controller to perform a comparison between one or more portions of the generated electric-field image and a library with stored images or data associated with one or more attributes, such as size, type, morphology, distribution, concentration, number of cells/microparticles, and so forth.

In some embodiments, the system 100 can include multiple-sensor areas or regions with different sensor pitches/dimensions for targeting smaller particles (e.g., microparticles) vs. larger particles (e.g., cells). For example, a first area with larger sensor pitch can be used to image cells or larger particles. This can be useful in cases where smaller particles are not of interest and/or cases where speed is more important than resolution. On the other hand, a second area with finer sensor pitch can be used to collect higher resolution electric-field images and detect microparticles and/or resolve cellular structures. At finer resolutions, both large and small particles may be detected.

In some embodiments, the system 100 can be configured to collect multiple electric-field images taken at different times (e.g., time lapsed images) to monitor growth or movement of cells/microparticles. For example, time lapsed images can be used to monitor cells as they multiply or for agglutination assaying to monitor movement of dispersed particles (e.g., antibody-coated microbeads 114 shown in FIG. 2A) as they agglutinate in the presence of an antigen (e.g., as shown in FIG. 2B). The electric-field imaging system 100 can be configured to perform agglutination or agglomeration assays including, but are not limited to, immunoassays, kinetic agglutination assays, agglomeration-of-beads assays, kinetic agglomeration-of-beads assays, coagulation assays, kinetic coagulation assays, surface antigen assays, receptor assays from biopsy procedures, circulating blood cells assays, and/or circulating nucleic acid assays (see, e.g., Michael Fleischhacker et al., Circulating nucleic AIDS (CNAs) and cancer—A survey, Biochimica et Biophysica Acta (February 2007)). For example, the electric-field imaging system 100 can have an active sensor area with a sensor pitch that is higher frequency than a Nyquist spatial sampling rate suitable for detecting a smallest member of a group of one or more target analytes (e.g., beads, cells, etc.) in the fluid sample for the assay being performed. In some implementations, the system 100 and the fluid sample for performing the assay can be provided as a “kit” (e.g., an electric-field imaging based assay kit).

Applications of functionalized bead technology for the electric-field imaging system 100 and diagnostics mainly apply to immunoassays, but can apply to other agglutination/agglomeration assays as well. There are hundreds of analyses that can be tested in this field. Functionalized beads may also be useful in coagulation assays as image enhancers if red blood cells are difficult to resolve. For example, instead of relying solely on the red blood cells, electric-field imaging system 100 can image the movement of beads along with the red blood cells as a clot is forming. Beads can also be used as internal standards to help verify object sizes (e.g., size of blood cells when doing complete blood counts) because the beads are manufactured with a known size (e.g., known diameter or diameter within known range). Beads used for electric-field imaging applications can include, but are not limited to: plastic (e.g., PolyStyrene (PS)) beads with, sizes (diameter) ranging from 50 nm to 13 μm; PS coated beads, sizes (diameter) ranging from 40 nm to 5 μm; PS coated beads, sizes (diameter) ranging from 5 um to 35 μm; ferromagnetic beads (e.g., chromium dioxide coated PS beads), sizes (diameter) ranging from 2 μm to 120 μm; paramagnetic beads (e.g., magnetite coated PS beads, possibly with variety of coatings), sizes (diameter) ranging from 100 nm to 120 μm; gold or silver colloids (particles/sols), sizes (diameter) ranging from 2 nm to 250 nm; or other commercially available beads.

The range in size for any one bead size supplied is typically 10 to 20% of the mean size. Typically, the more narrow this range the more expensive the product will be. Plastic beads may have more of an effect on the electric field, so they should be easier to resolve than red blood cells or other biological cells. Metal-containing beads may have even more of an effect on the electric field, so they should be even easier to resolve than plastic beads. Magnetic beads are useful for separation, which may have specific applications for the electric-field imaging system 100, for example, for tracking growth or movement of a particular cell type with respect to others, where the monitored cells are tagged with magnetic beads for easier separation. Smaller/lighter beads will result in a faster reaction, while larger/heavier beads will result in a slower reaction. However, larger beads can be more easily resolved by the electric-field imaging system 100. As demonstrated by the foregoing examples, certain bead types and/or sizes will have advantages over other bead types and/or sizes depending on the application and factors being considered (e.g., reaction time vs. resolution, and so forth).

In embodiments, the system can further include a thermal sensor configured to detect a temperature of the fluid sample containing the biological cells or microparticles and/or a conductivity sensor configured to detect a conductivity of the fluid sample or portions thereof. In some implementations, the impedance-based sensor itself (e.g., one or more of the metal panels 102) can be configured to detect the conductivity of the fluid sample or sample conductivity at different regions of the active sensor area.

In some embodiments, the electric-field imaging system 100 relies on a substantially vertical electric field. As shown in FIG. 3, for example, a driving electrode 120 can be located above the electric field sensor array defined by the metal panels 102. In some embodiments, the metal panels 102 are covered by an insulator 116 (e.g., glass or plastic substrate) that separates the metal panels 102 from the fluid 118 containing the target analytes (e.g., cells 110, cellular structures 112, etc.). The driving electrode 120 can induce a vertical electric field that is formed between the driving electrode 120 and the sensor array of metal panels 102 disposed below. The electric-field imaging system 100 can additionally or alternatively rely on a substantially horizontal electric field. For example, as shown in FIG. 4, a single pixel/panel 102, line of pixels/panels 102, or one or more regions of pixels/panels 102 can be driven, and the rest of the pixels/panels 102 in the electric field image sensor array can detect the electric field generated by the pixels/panels being driven. The presence of analytes like microparticles, viruses, cells, in the fluid disturbs the electric field (e.g., changes in impedance or charge detected from driving pixel/panel 102 to receiving pixel/panel).

In some embodiments, the driving electrode 120 or an insulator 122 (e.g., glass or plastic substrate) is positioned over the fluid sample, such that the fluid sample is sandwiched between the active sensor array and the electrode 120 or insulator 122. Positioning of the electrode 120 or insulator 122 can be used to limit the possible distance between target analytes in the fluid and the metal panels 102 of the sensor array. In some embodiments, the distance is limited to approximately 10 microns or less.

Example Processes

FIG. 5 shows a flow diagram for a method 200 of imaging target analytes with an electric-field imaging system, such as the system 100 described herein. Accordingly, the method 200 may include any steps or operations that are described herein with regard to the electric-field imaging system 100 or that are necessary for achieving an attribute of the electric-field imaging system 100 that is described herein. However, the method 200 is in no way limited to any embodiment of the electric-field imaging system 100 described herein.

As shown in FIG. 5, the method 200 can include: (202) placing a fluid sample (e.g., blood sample or other biological sample) on an active sensor area of an impedance-based sensor (e.g., system 100), the fluid sample containing target analytes (e.g., biological microparticles, viruses, cells, beads, or the like); (204) generating an image based upon changes in impedance or charge caused by the target analytes in the fluid placed on the active sensor area; and (206) determining one or more attributes of the target analytes based upon the generated image. In some implementations, determining the one or more attributes of the target analytes based upon the generated image (step 206) can include performing of a comparison between one or more portions of the generated image with a library of stored images or data structures. For example, computer imaging algorithms may be executed by one or more processors to perform comparisons with a library of stored images or parameters to determine attributes of the microparticles, viruses, cells, or beads including one or more of: size, type, morphology, volume, distribution, number, concentration, or motility of the target analytes.

In some implementations, the impedance-based sensor can include multiple active sensor areas or regions (e.g., as discussed above with regard to system 100) with different respective sensor pitches suitable for detecting differently sized particles (or different ranges of particles sizes). The method can further include as step of selecting a first sensor area or a second sensor area based upon a size of the target analyte being imaged.

In some implementations, the method can further include generating a second image based upon changes in impedance or charge caused by the target analytes in the fluid placed on the active sensor area, the second image being generated at a second later point in time relative to the first image. For example, time lapsed images can be used to monitor cells as they multiply or for agglutination assaying to monitor movement of dispersed particles (e.g., antibody-coated microbeads 114 shown in FIG. 2A) as they agglutinate in the presence of an antigen (e.g., as shown in FIG. 2B).

Those skilled in the art will appreciate that the forgoing steps or operations can be carried out in any order, unless otherwise indicated herein, and that one or more steps may be carried out substantially simultaneously or at least partially in parallel. It should be further recognized that the various functions, operations, blocks, or steps described throughout the present disclosure may be carried out by any combination of hardware, software, or firmware. Various steps or operations may be carried out by one or more of the following: electronic circuitry, logic gates, multiplexers, a programmable logic device, an application-specific integrated circuit (ASIC), a controller/microcontroller, or a computing system. A computing system may include, but is not limited to, a personal computing system, mainframe computing system, workstation, image computer, parallel processor, or any other device known in the art. In general, the terms “controller” and “computing system” are broadly defined to encompass any device having one or more processors, which execute instructions from a carrier medium.

Program instructions implementing methods, such as those manifested by embodiments described herein, may be transmitted over or stored on carrier medium. The carrier medium may be a transmission medium, such as, but not limited to, a wire, cable, or wireless transmission link. The carrier medium may also include a non-transitory signal bearing medium or storage medium such as, but not limited to, a read-only memory, a random access memory, a magnetic or optical disk, a solid-state or flash memory device, or a magnetic tape.

It is further contemplated that any embodiment of the disclosure manifested above as a system or method may include at least a portion of any other embodiment described herein. Those having skill in the art will appreciate that there are various embodiments by which systems and methods described herein can be implemented, and that the implementation will vary with the context in which an embodiment of the disclosure is deployed.

Furthermore, it is to be understood that the invention is defined by the appended claims. Although embodiments of this invention have been illustrated, it is apparent that various modifications may be made by those skilled in the art without departing from the scope and spirit of the disclosure. 

1.-20. (canceled)
 21. A system for analyzing a fluid sample, comprising: an impedance-based sensor including a plurality of metal panels that define an active sensor area for detecting at least one analyte in a fluid sample; and a processor configured to receive electrical signals associated with detected impedance or charge or detected changes in impedance or charge from the plurality of metal panels when the fluid sample is placed on the active sensor area, the processor further configured to assess at least one attribute of the at least one analyte in the fluid sample at least partially based on the electrical signals associated with the detected impedance or charge or the detected changes in impedance or charge.
 22. The system of claim 21, wherein the at least one attribute comprises at least one of: size, type, morphology, volume, distribution, number, concentration, or motility of the at least one analyte in the fluid sample.
 23. The system of claim 21, wherein the processor is configured to generate an image or data based upon the electrical signals associated with the detected impedance or charge or the detected changes in impedance or charge.
 24. The system of claim 23, wherein the processor is configured to assess the at least one attribute of the at least one analyte in the fluid sample at least partially based upon a comparison of the image or data with a library of stored images or data structures.
 25. The system of claim 21, further comprising: a driving electrode positioned relative to the active sensor area, the driving electrode being configured to generate an electric field, wherein the plurality of metal panels that define the active sensor area are configured to detect the electric field.
 26. The system of claim 25, wherein the driving electrode is positioned a distance above the active sensor area, and the electric field generated by the driving electrode is a substantially vertical electric field relative to the active sensor area.
 27. The system of claim 21, further comprising: a first insulator positioned over the active sensor area, the first insulator being configured to prevent the fluid sample from directly contacting sensor elements of the active sensor area.
 28. The system of claim 21, further comprising a thermal sensor configured to measure a temperature of the fluid sample.
 29. The system of claim 21, further comprising a conductivity sensor configured to measure a conductivity of the fluid sample.
 30. The system of claim 21, wherein the impedance-based sensor is further configured to measure a conductivity of the fluid sample.
 31. A method for analyzing a fluid sample, comprising: placing a fluid sample on an active sensor area of an impedance-based sensor, the active sensor area including a plurality of metal panels, the fluid sample including at least one analyte; receiving electrical signals associated with detected impedance or charge or detected changes in impedance or charge from the plurality of metal panels when the fluid sample is disposed upon the active sensor area of the impedance-based sensor; and assessing at least one attribute of the at least one analyte in the fluid sample at least partially based on the electrical signals associated with the detected impedance or charge or the detected changes in impedance or charge.
 32. The method of claim 31, wherein the at least one attribute is at least one of: size, type, morphology, volume, distribution, number, concentration, or motility of the at least one analyte in the fluid sample.
 33. The method of claim 31, further comprising: generating an image or data based upon the electrical signals associated with the detected impedance or charge or the detected changes in impedance or charge.
 34. The method of claim 33, further comprising: assessing the at least one attribute of the at least one analyte in the fluid sample at least partially based upon a comparison of the image or data with a library of stored images or data structures.
 35. The method of claim 31, further comprising: generating an electric field with a driving electrode positioned relative to the active sensor area; and detecting the electric field with the plurality of metal panels that define the active sensor area, wherein the electrical signals are generated by the plurality of metal panels in response to detecting the electric field.
 36. An impedance-based sensor, comprising: a plurality of metal panels that define an active sensor area for detecting at least one analyte in a fluid sample; and a processor configured to receive electrical signals associated with detected impedance or charge or detected changes in impedance or charge from the plurality of metal panels when the fluid sample is placed on the active sensor area, the processor further configured to assess at least one attribute of the at least one analyte in the fluid sample at least partially based on the electrical signals associated with the detected impedance or charge or the detected changes in impedance or charge.
 37. The impedance-based sensor of claim 36, wherein the at least one attribute comprises at least one of: size, type, morphology, volume, distribution, number, concentration, or motility of the at least one analyte in the fluid sample.
 38. The impedance-based sensor of claim 36, wherein the processor is configured to generate an image or data based upon the electrical signals associated with the detected impedance or charge or the detected changes in impedance or charge.
 39. The impedance-based sensor of claim 38, wherein the processor is configured to assess the at least one attribute of the at least one analyte in the fluid sample at least partially based upon a comparison of the image or data with a library of stored images or data structures.
 40. The impedance-based sensor of claim 36, further comprising: a driving electrode positioned relative to the active sensor area, the driving electrode being configured to generate an electric field, wherein the plurality of metal panels that define the active sensor area are configured to detect the electric field. 